It takes time for society to digest changes, but we are changing. We can not deny climate change anymore and, as a species, we have come to realize there is an urgent need to change our energy generation habits. They have changed indeed and, in the last decades, renewable energies have clearly colored the picture of energy sources.
Particularly, wind energy is called to be one of the most valuable cards in the hand of renewable energies in the near future. However, the current trend, and target of this thesis, are not the typical wind turbines installed inland. In the last years, the preferred location for the placement of wind farms has traveled, or we better say sailed from land to the seas, seeking for higher efficiency and exploitation of wind’s potential.
Even though there are reasons to carry wind turbines offshore, the trip is neither easy nor low-cost and implies the analysis and design of new substructures to bear the weight of the turbines. Those substructures are called jackets.
This thesis defines a procedure of analysis of the dynamic behavior of offshore wind turbines supported by jackets. Upon that analysis, a structural optimization problem is defined and solved using mathematical and numerical optimization techniques. The goal is to reduce the amount of material needed to manufacture the jackets and therefore reduce the investment of offshore wind turbine structures and consequently the indirect cost of energy production.
The structural model is based on a non-linear dynamic analysis of three dimensional framed structures for fully coupled offshore wind turbines considering the rotation of the blades. Special care is taken in the description of the environmental loading conditions.
Wind and wave actions and forces on the elements of the structure are thoroughly modeled. One of the most decisive aspects in the design of offshore structures is fatigue in steel elements arising from cyclic loads. In this thesis fatigue damage is assessed in terms of S-N curves by means of the Palmgren-Miner rule and using the Rainflow algorithm for counting stress cycles. Long-term fatigue damage in the joints of the jackets is accurately estimated from the damage computed for short-term computational simulations.
Since the analysis of the jackets is addressed in the time domain, the problem is faced as a dynamic response optimization. Although there are a few methodologies to handle time-dependent constraints, none is able to accomplish the task efficiently and still retaining all the valuable information about the structural status. A novel methodology is introduced to efficiently deal with the time-dependent structural constraints imposed to the dynamic response of the structure.
The optimization model is presented as a weight minimization of the steel jacket under Ultimate Limit Stress, Fatigue Limit State and frequency constraints. Crosssections of the tubular elements and bottom and top widths of the jacket are chosen as design variables to perform a simultaneous shape and size optimization while preserving the straight alignment of the legs. The optimization is addressed using Sequential Linear Programming which requires a first order sensitivity analysis. The sensitivities are obtained through Direct Differentiation and analytic derivatives except for the fatigue damage constraint since it lacks analytic derivative. The sensitivity core of the computational code constitutes an extremely expensive part in terms of CPU time and storage.
The optimization methodology developed is applied to real jacket structures bearing fully coupled rotating wind turbines. The optimization results show fair robustness of the algorithm when facing different problems and substantial reductions in the weight of the steel jackets are obtained while guarantying the fulfillment of the conditions imposed by the structural standards.
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